Control means for dehumidifying apparatus



July 24, 1951 W. LOU

CONTROL MEANS FOR DEHUMIDIFYING APPARATUS Filed Feb. 4, 1949 4 Sheets-Sheet 1 IN VEN TOR.

ATTRNEYS.

July 24, 1951 w. Lou

CONTROL MEANS FOR DEHUMIDIFYING APPARATUS 4 Sheets-Sheet Filed Feb. 4, 1949 IN V EN TOR.

ATTORNEYS WYAN LOU. BY

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CONTROL MEANS FOR DEHUMIDIFYING APPARATUS 4 Sheets-Sheet 3 Filed Feb.- 4, 1949 ooo' xa INVENTOR. WYAN LOU. BY

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CONTROL MEANS FOR DEHUMIDIFYING APPARATUS `uly 24, 1951 `4 Sheets-Sheet 4 Filed Feb. 4. 1949 Patented July 24, 1951 CONTROL MEANS FOR DEHUMIDIFYING APPARATUS Wyan Lou, New York, N. Y., assignor to Cargocaire Engineering Corporation, New York, N. Y.,

a corporation of Delaware Application February 4, 1949, Serial No. I75,781

(Cl. 18S-4.7)

14 Claims.

This invention relates to electronic control apparatus, and more particularly to such apparatus for governing a dehumidifying device.

Consider, for example, a dual bed type of dehumidier. Each' bed or adsorber of such a device contains a chemically inert drying agent, or

l. desiccant, which has the ability to remove water vapor from the air lwhich comes in contact with it The process of so removing water vapor is known as adsorption When the bed becomes saturated with moisture it is necessary to remove the latter by a process known as reactivation Heat is applied directly or indirectly to the adsorber for this purpose, for example, hot air is directed through the saturated bed.

In a dual bed dehumidier, hereinafter referred to as a D/H unit, of the type mentioned above, the desiccant beds or adsorbers are alternately on adsorption and reactivation. That is, while one is removing moisture from the air, the other is being reactivated or regenerated. The requirements for efficient operation of such a dual bed D/H unit are:

(l) One adsorber `should be kept on adsorption until its maximum useful capacity has been `reached under all conditions of dry-bulb temperature and relative humidity of the entering said to be capable of operating under maximumv moisture load conditions. A dual bed D/H unit in order to operate under these conditions must be provided with sufficient heater capacity to reactivate one of the desiccant beds Within a period which is approximately equal to the time required for adsorption. Under less than maximum moisture load conditions, the adsorption period will length, as compared to that for maximum conditions, and the reactivation period will shorten. 'I'he present invention is designed to control a D/ I-Il unit which is adapted for operation under maximum moisture load conditions.

lIhe ideal control for such a unit, as embodied in the present invention, is one which Will stop reactivation on one bed when that phase is com,

plete, as indicated in requirement (2) above, allow adsorption to continue on the other bed, and switch the cycles only when adsorption is completed as indicated in requirement (l) above.

Certain of the variables which can be used for giving a reliable indication of the states of the adsorber beds at any time during both adsorption and reactivation, in order to meet requirements (1) and (2) above, are, for example, drybulb temperature, dewpoint, and relative humidity.

In a practical electronic control of the type described herein, a device for sensing a variable, such as one of those above mentioned, must be dependable, and accurate within reasonable limits. Of the above variables, temperature can be readily measured and numerous sensing devices are available for the purpose, which devices are simple, inexpensive, of constant characteristics, rugged, and require little or no attention for maintenance.

The present invention employs temperature measurement to determine the states of the desiccant beds.

With respect to reactivation, usually air is employed as the reactivation medium and is heated to a constant temperature for the purpose, and pumped at substantial velocity through the moisture laden bed. The hot air carries away the moisture held by the desiccant. At rst the wet air exhaust (eluent reactivation air) is relatively cool due to the large amount of heat given up in raising the temperature of the desiccant and its housing which is usually of metal. As Water is driven out of the desiccant, the Wet air exhaust temperature rises and remains fairly constant for a substantial part `of the cycle. Towards the end of the cycle when all or most of the water has been removed, the ellluent air temperature rises and approaches the input air temperature. A certain effluent temperature near the end of the cycle can be selected at which. toterminate reactivation, because further application of heat will not result in much more benet.

Regarding adsorption, input air is directed to an adsorber, for example, by a pump or fan, and the temperature of the input air normally remains constant or substantially so throughout a given adsorption cycle. The eluent air temperature is normally high at first due (a) to the high temperature of the adsorber housing and related structure, and the desiccant which has been recently reactivated; (b) to heat of adsorption, that is, as the desiccant removes moisture from the air, heat is liberated. Heat of adsorption, of course, will manifest itself Whether or not the adsorber is hot or cold at the beginning of the cycle. The amount of heat liberated depends on the rate of adsorption. With a substantially constant now of air through the desiccant, the difference in temperature between the inlet and efuent air can be taken as a measure of the amount of moisture which has been adsorbed and also the rate of adsorption. The eiiluent air temperature willgradually diminish and approach the inlet air temperature. At a selected minimum temperature diierential, AT, the adsorber is saturated up to its maximum useful capacity and can be switched over to reactivation.

However, the minimum differential for ,optimum performance of the D/H unit is not theY same for all inlet air conditions. This diierential varies with the inlet temperature.V

Control devices of this general character suggested in the past have failed 1to take into Aaccount and to provide for variations in 'this'minimum temperature differential.

Moreover, prior control apparatus of this nature haveicomrnonly switched theradsorption-and reactivation Icycles after a :xed -time period metered-as by-a clock. v-Of course, a repeat period calculated to. `produce optimumrperformance wfor one -setof conditions will notV give suchperforma-nce'for othersets `of conditions.

This invention in one aspect thereof comprises: V(-1-) -Control -means .for stopping reactivation -w-hen the application-of further heat willi-not result in any appreciable benet. Thus a considerable energy saving can be eiiected. Such means, in the -form.shown, comprise .anel'ement .for sensing the temperature of the reactivation wet -air exhaust, and .forshutting off the flow of heated air to the adsorber undergoing reactivaytion-at apreselected temperature.V The temperature sensing element, for example, isv aresistance which is electricallyassociated -with a ,thermionic V.valve device which is .adapted for emitting ,a

stop-reactivation signal of predetermined/,short duration whenever the .preselectedtemperature is reached.- This signalisdirected to an. fon-01T switchingcrcuit,in which is Alocated `a relay for ...governing .areactivation faniorv pump. {Energization `of the on-,oifWci'rcuit 'by said signal,. of

" course, Vwil-l stop thereactivationfan.

L2) .Control means-forswitching the cycles of .the desiccant beds, for example, vby switching .a

lof the .cycle switch-over., they must continue in loperation Under certain conditions, the means fior. generating av stop reactivation signal may be delayed inY operation .and such a signal gen- .erated thereby may be received by the reactivation meansA immediately after a switching of cycles which would destroy the proper sequence of events and present reactivation of a Wet bed; 4electronic means are provided for preventing .such Va signal from stopping reactivation.

As` above mentioned, temperature is herein employed f or measuring the state of the adsorber undergoingadsorption. The temperature of inlet and eiiluent adsorption air are measured, and

at aA preselected differential therebetween the novel electron-icrcontrol means bring about the jcycle change-over and restart reactivation or per- --mit theY latter to continue if underway at i the'time of ,the--change-over.` Said inlet-and` efuent Atemperatures are sensed, for example, by resistance elements-which preferably have negative temperature coecients and the tempera- .4 ture-resistance characteristics of which are preselected whereby the resistances ofthe two elements are equal overl a predetermined range of temperature differentials, the differential being .a function of the inlet-air temperature. A bal- :ance between the sensing resistance elements is determined, for example, by a bridge circuit and the state of balance is employed to trigger a normally quiescent oscillator or thermionic valve circuit for generating a cycle change-over signal of predetermined short duration. Such a circuit vis constituted by an -oscillator circuit which responds -to a :balance of said bridge. The cycle changeoversignal is directed to a relay for governing the ,air valves of the D/H unit, the con- 'nectionbeingthrough for example, a trigger circuit which emits a signal which in turn actuates a circuit variously known as a sequence switching, .afcounten ora flip-nop circuit, the relay being connected 'in the vlatter circuit and alternately `energized and deenergized by succeeding signals from said oscillator circuit through the intermediary of .the suitable .trigger circuit. The trigger circuit is reset, that isyprepared to emit the next signal by a suitable reset circuit responsive to both the cycle change-over signal ,and the stop reactivation signal. The output signal ofthe trigger circuit'isadapted for persisting at least as long as .the cycle change-over signal and said circuit isV interconnected with the reactivation side torestart reactivationif stopped, .or to permit reactivation to continue if it is underway. The trigger circuit 4also provides, during the vperiod .of `its signal, `a shield 'to-1pre vent'an oncoming "stop-reactivationsignal from becoming effective. This shield is` effective up `tothe end of a stop-reactivation 'signal providing thev latter occurs 'during a cycle changeover signal.

One ofthe vobjects of the present invention is to overcome the defectsl above lmentioned-in connection with prior Yapparatus nof "this character.

The vabove and further ob'jects'and'novel features iwill more fully appear'fromthe'detailed-description when the. same isfreadlin connection with the accompanying drawings.. Itisto be expressly understood', however, that. the drawings `are for purposesof illustration only and are not intended as a definition of vthel limits of the invention, reference for this"latter purpose being had tothe appended claims.

In the drawings, wherein like reference characters refer to like part-s throughout the several views,

Fig. 1 is a schematic diagram of one form of dehumidifier unit with which the novel control device can be employed;

Fig. 2 is a graphical representation of reacti- -Vaton tempera-ture characteristics of the device of Fig. 1;

Fig. 3 is a graphical representation of adsorption temperature characteristics of the device of Fig; 1;

Fig. 4 is a graphical showing of variationin a critical temperature differential which is `measured by the presentinvent'ion;

Fig. .5 is a so-called block .diagram illustrating schematically the electrical `interconnections of certain elements .of Vone. form ofthe present invention;

Fig. 6 is a graphical illustration ofY changes in resistance with change in temperature of temperature sensing resistance elements employed in the present invention; Y

Fig. 7 is a schematic showing of a bridge circuit in` which said temperature sensing resistance elements can be employed;

Figs. 7a and '1b indicate specic forms of said temperature sensing elements having .compensating resist-ances associated therewith;

Fig. 8 is a wiring diagram showing detailed schematic representation of one embodiment of the invention;

Fig. 8a is a graphical representation of voltages occurring in one of the circuits embodied in the present invention.

Referringto the drawings, a dehumidifier apparatus, which is adapted for being controlled by the novel invention herein disclosed, is illustrated in Fig. 1 and is constituted by a pair of adsorber beds 2D and 2l which are each iilled with a desiccant such as silica gel. The adsorber beds 20, 2l are adapted for being alternately placed in adsorbing and reactivation cycles by a pair of socalled four-way air valves 22 and 23` which are respectively in communication with said beds by means of conduits 24, 25 and 2B, 21 in a well known manner. Air intake for adsorption is directed to an inlet orifice 22a of the valve 22 by means of a suitable air pump or fan 28, and hot air for reactivation is directed to an inlet orice 23a. of the air valve 23 b-y means of a suitable hot air fan 29. Wet air exhaust is emitted from a conduit 30 which is in communication with the air valve 22 and a dry air outlet is provided at 3l which is in communication with the outlet orifice of the valve 23.

The valves 22 and 23 are, of course, provided with suitable movable valve elements such as yplates 22h andl 23h which yare operatively interconnected preferably by mechanical means and adapted for being shifted angularly together. In

the position shown of the valve plates 22h and 23h, the left hand adsorber is undergoing a reactivation cycle and the right hand adsorber 2l is undergoing an adsorption cycle. An angular change of 90 of said valve plates will cause a switching of the cycles.

The angular shifting of the valve plates can be effected, for example, by means of a pneumatic piston apparatus or element 32 having a control valve 33 which preferably is held against one limit of its motion by means of a suitable spring as at 34. The valve 33 can be shifted from one limit of its motion, as shown in Fig. l, to the opposite limit, for example, by means of a solenoid 35 which is adapted vfor overcoming the spring 34. Thus energization of the solenoid 35 will shift the valve plates 22h and 23h from the position sh-own in Fig. 1 through an angular increment of 90.

The solenoid 35 for governing the pneumatic piston device 32 can be in circuit with a suitable source of electric energy as at 36 and under the influence of a relay 31. The energization of the relay 31 is adapted for closing normally open switch 38, thereby completing the circuit of the solenoid 35. The operation of the relay 31 will appear more fully hereinafter.

The above-mentioned motor 29 which pumps heated -air to the bed undergoing reactivation is under the influence of a relay 39 having normally closed contacts 40, which relay also acts in a manner to appear more fully hereinafter.

In Fig. 2, there is a graphical showing of the variation of wet air exhaust temperature during a period of reactivation on a typical D/H unit as that shown in Fig. 1. The air is heated to a constant temperature Ta, for example, 300 F. and is directed through the wet adsorber as at 20. The hot air carries away the moisture held by the desiccant. At rst the air emerging from the mationed.

:chine through the conduit 30 is relatively cool due to the large amount of heat given up in raising the temperature of the desiccant and the housing structure of the adsorber. As water is removed from the desiccant, the wet air exhaust temperature rises and remains at a fairly constant level as indicated on the curve at T4. Towards the end of the reactivation cycle when all or most of the water has been removed, the temperature rises and approaches Ts. At a certain temperature, for example, Tx, the reactivation should be cut off because beyond this point any further application of heat will not result in much more benet.

`In Fig. 3 there is a graphical representation of the variation of temperature on the adsorption side of the apparatus. For example, T1 represents the temperature of the inlet air which normally remains constant or substantially constant throughout a given cycle of adsorption. T2 represents the temperature of the dry air issuing from the adsorber, that is, effluent temperature.

T2 is initially relatively high due to: (l) The high temperature of the adsorber structure as the housing mechanism and also due to the fact that the desiccant bed has previously been reactivated with hot air. This, of course, is an inherent characteristic of this type of machine. (2) As the desiccant removes moisture from the air, heat is liberated. This is called "heat of adsorption as above mentioned. Thus heat is given up to the dry air raising its temperature as it emerges from the adsorber. The amount of heat liberated, as has also been mentioned above, depends upon the rate of adsorption. Consequently, if a relatively constant flow of air is directed through the desiccant, the difference in temperature between the inlet and the outlet air can be an indication of the rate of adsorption and the amount of adsorption. T2 gradually diminishes as the adsorber bed becomes more saturated and at some minimum temperature differential the adsorber is saturated up to its maximum useful capacity and should be switched over to the reactivation cycle.

It is important to note that the minimum temperature differential for optimum performance of the D/H unit is not the same for all inlet air conditions. This minimum temperature differential varies with the inlet air temperature in the manner shown in Fig. 4. The novel control apparatus described herein takes into account this variation in minimum tem perature differential in a manner to appear more fully hereinafter. For example, with one type of D/H unit, it has been found that the minimum temperature differential at which the adsorption cycle should be terminated is 16 when the inlet temperature T1 is 0 F. When the inlet temperature rises, for example, to 113 F., the optimum minimum temperature differential has been found to be 50 F.

The novel apparatus described herein fulfills the following requirements in so far as the sequence of operation is concerned: (a.) Reactivation is stopped when it is completed to an economical point as above mentioned, (h) The air valves on the D/H unit are switched when the desiccant undergoing adsorption has been saturated to its economical limit also as above men- (c) When the valves are switched, the reactivation mechanism must be restarted if it has been stopped or it must be permitted to continue in operation if it is under way. (d) If, due to atime lag, in response to the reactivation conl trol device,.the reactivation exhaust temperature sensing element should call for a stopping of re- 7 activationimmediately following'the switching of the/valve, then reactivation must not ceaseand means-are provided for preventing the stop reactivation signalfromI becoming effective.

I have found that the pair of temperature sensitive resistance elements which preferably are properly compensated as by shunt resistances, and connected into a bridge circuit with two standard resistors, can be: successfully employed toA measure the above-mentioned temperature differential which' can vary-from cycle tocycle, depending upon the inlet air temperature. Two SuchV resistance elements or resistors 4l; :i2 are indicated in Figs. 7, 7a, 7b and 8 and are; preferably compensated by shunt resistors 43' and 44 respectively to provide the desired temperatureresistance characteristics as in Fig. 6 The temperature sensitive resistors 4|, i2 with their respective shunt resistors are respectively referred to as R-in and R-out. It is not absolutely necessary to compensate 4I and 42 as above vbut it has been found desirable in order to assist in producing said desired characteristics.

In Fig. '7 the resistors are shown in a balancing bridge i5 with two of the balancing arms constituted by R-in and R-out, and the twoiixed ratio arms constituted by xed resistors 16, lll, the latter two are also referred to as Rm and Rkz. The two conjugate arms of the bridge are indicated as at ab andcd. A regulated constant direct current potential, as 165 volts is applied across arm ab.

The graph indicated in Fig. 6 shows how` the temperature sensing resistors can be employed for measuring a varying temperature differential. R-.in and R-out are, in the form shown, so compensated that they provide substantially straight line resistance characteristics as in Fig. 6, and they are so chosen that their substantially straight characteristic lines diverge insuch a manner that, for equal resistances, that is when the resistances are in balance, a temperature diierential exists therebetween which for a given R-in is constant but which can vary in response to a change in'R-in or in the resistance at which bridge balance occurs. Thus the temperature sensing resistors are so chosen that only when there exists certain desired differences in temperature between them, their resistances will become equal, and these diierences will depend upon the temperature of R-in. A bridge null detector is devised to utilize bridge `balance as a c control factor.

I have found it desirable to, employ thermal resistance elements Rn and R-out which have negative temperature coefhcients. Such resistors, at the present time, are made from' a class of materials known as semi-conductors,y that is, materials whose conductivity lies between that of conductors and insulators. These resistorsl are normally known as thermistors. Thermistor materials are usually comprised of various combinations of manganese, nickel, cobalt, copper and other metallic oxides and the resistance thereof increases rapidly as the temperature falls and vice versa, the resistance decreases as the temperature rises. l

Positive temperature coeiiicient resistors, of course, can be employed but the negativetemperature coefcient resistors are preferable because of an unusually large numerical coefficient. Thus the negative temperature-coefficient materials have temperature-resistance curveswhich are of greater slope than similar curves for substances having positive temperature coefficients.

Thus if substances having a positive temperature,

8, coefficient are used, the slope of theirtemperature resistance curves may be lower and. conse.- quently require much higher sensitivity inthe measuring device. This may lead to considerable error in the event that the measuring devices are not in fact'extraordinarily sensitive. The use of thermistors or negative temperature coeicient substances permits the use of electronic measuring circuits which need not have extraordinary sensitivity.

Thus the characteristics of the negative temperature coeiiicient resistors are ideal for temperature sensing elements to be employed in the present invention. Such thermistors aresmall, light and inexpensive. Moreover, no moving parts'are involvedand consequently little or no maintenance is required. The wide operating range of the thermistors more than covers the temperatures which normally are encounteredin D/H units.

It was mentioned above that a bridge null detector is employed to utilize the bridge balance as a control factor. I have found that itis advantageous to employ bridge balance as a control factor because of the great difficulty of measuring the very slowly varying D. C. potential which occurs in the bridge shown as in Fig. '7. The variation ofv this D. C. potential may be only a small fraction of a volt over a period of several minutes and an electronic circuit to be sufficiently sensitive to respond to such a change would have to be extraordinarily sensitive and expensive. Moreover, it would be subject to power line voltage fluctuations; and changing tube characteristics; variation of characteristics of the tubes with tube replacements, and many other factors such as circuit complications and so forth. Thus the actual measurement of such a direct current or of a D. C. potential is not considered desirable. However, if necessary, such measurement can be made and still be within the purview of the present invention. The embodiment described herein employs the point of bridge balance as the control factor, whichinitiates a cycle change-over impulse with one bridge, and also a stop reactivation impulse by means of another` bridge.

Thus, in the form shown of the present invention, two bridges are employed, one for sensing the differential between inlet and eluent air for the adsorption side of the device, and another for sensing the reactivation exhaust temperature. The two bridges .are preferably supplied withr a regulated direct current voltage from a common source and to prevent inter-reaction are decoupled in a manner to appear below.

Adsorption side bridge balance signalling means The bridgeV balance signalling means are also referred to as a bridge null detector and a bridge null'` detector oscillator. Said device includes an oscillating circuit whichnormally is quiescent when the bridge isV out of balance. However, as soon as the bridge comes into balance an alternatingjsignal voltage ofV large magnitude appears at the output of the oscillator. The bridge balance signalling means are novel in that they are normally quiescent and are not actuated until bridge balance exists. I have found that a multivibrator type circuit under the influence of a trigger'tube'such as a diode produces a bridge balance signal of desired characteristics. The signal voltage from the multi-vibrator in combination with such a diode is=a uniform one and maintains itself without fluctuation after the kbridge passes through its balance pointandA bel.above set forth is from the plate of tube via 9 comes unbalanced. When the bridge passes back into its original unbalanced state, the output signal of said oscillator does not instantly stop but is maintained steadily until a predetermined degree of bridge unbalance is reached at which time it abruptly stops. The circuit is such that the output signal is anti-hunting and there is a predeterminable time difference between the commencing and the terminating of the signal. This is accomplished electronically and without .the use `of any other external signal or initiating impulses.

In conjunction with the bridge balance signalling device above mentioned, there are employed, in the form of the invention shown, certain thyratron tubes which are adapted for controlling the above-described valve control relay 31. These thyratron tubes are designed for operation on direct current with alternating current upon the grids thereof. Consequently it is desirable for the bridge balance signalling means to produce an alternating currentsignal of a predeterminable duration. The circuits and operation of said thyratrons will be more fully explained hereinafter. It is, of course, possible to operate said thyratrons with alternating current across the cathodes and anodes. Alternating or direct current may be used on any and all electrodes of such thyratron tubes. However, this invention is especially adapted for use aboard vessels such as merchant ships wherein, for example, 230 volt direct current is usually, available.

Consequently, it is desirable for the bridge balance signalling means to be able to produce an .alternating current in response to a direct current "signal for the purpose of controlling the thyra- ,tron circuit above mentioned.

Said bridge balance signalling device is indicated as at 48 and includes a diode 49 and triodes 5U and 5|. The triodes 50 and 5| are interconnected as a multivibrator. That is, the plate of eachtriode is connected to the grid of the other triode. One of such connections between the plate and grid `contains in shunt the rectifier 49 and a conjugate arm of the balancing bridge 45.

.The plates of tubes 50,` 5| are connected to a regulated source of direct current 52 of, for example, 150 volts, by means of leads 53, 54, respectively. Suitable plate resistors 55, 56 are interposed respectively in said leads.

.The cathodes of tube 50, 5| are respectively connected to ground through cathode =plate current biasing resistors 51,58.

The plate of tube 5| is connected to the grid of vtube 50 via a lead 59 connected at point 60 to plate lead 54. Interposed in lead 59 are (a) resistance 6|; (b) condenser 62; (c) diode 49; and (d) condenser 63. A grid resistor 64 for tube 50 is connected to lead 59 intermediate condenser 63 and said grid.

The plate of tube 50 is connected to the grid of tube 5| by a lead 65 having therein a condenser 66, and having at point 61 a grounded lead 68 connected thereto in which is interposed a grid resistor-69. Connected in shunt with the diode 49 is a conjugate arm cd of bridge 45 by means of leads 10, 1|,

the latter having interposed therein a load resistor 12 for the tube 49.

The feedback path of the multi-vibrator circuit-` resistance 6|, condenser 62, diode 49 and condens- `er 63. Diode or rectifier 49 `acts as an on-off switch completing or breaking the feedback cir- V4cuit in` response to thebalanceof bridge 45. The

l0 onfcff` tube 49 can baby-passed via a normally open manually operable push-button switch 13 as shown. Pushing of this button completes the feedback path around diode 49 and causes the circuit to oscillate regardless of bridge balance, and for the duration ofthe closing of switch 13. Diode 49 is connected in feedback relation with said multi-vibrator. For example, the anode thereof` is coupled to the control grid of one of said tubes and its cathode is coupled to the plate of the othertube. Diode 49 thus yconstitutes a normally quiescent thermionic valve electrically connected to and `controlling the oscillator comprising the multi-vibrator.

Bridge 45 is powered by a source 14 of regulated direct current of, for example, volts via leads 15, 16.

If We assumenow that the bridge 45 is out of balance with the resistance of R-out less than R-in, that is the temperature T2 is higher than T1, with RKi (46) and RKz (41) remaining constant and equal, point d of the bridge 45 will be at a lower potential than point c. Thus the plate of the rectifier or diode v49 will be negative with respect to the cathode thereof. Tube 49 consequently` will not pass current because the feedback path `of the circuit of oscillator48 is open and thus no oscillation can occur. Then gradually as the temperature T2 drops, the resistance of R-out slowly increases until it becomes equal to R-in. At this instant the bridge is in balance and points c and d are at the same potential. The diode 49 will then conduct. Electron flow will be ampliiied by tubes 50 and 5| and will be fed back in phase through the diode 49 to reinforce the original voltage. The feedback path is as above set forth. Only `negative pulses or voltages can pass through the rectier 49` but this is sufficient for operation of the` circuit. The feedback voltage will appear` across the load resistor 12, and in view of its pulsating nature will also appear across the grid resistor 64. Oscillation will build up and a pulsating output signal voltageof large amplitude will appearacross the plate resistor 56 of the tube 5 A so-called contact potential effect may exist with respect tothe diode 49 which may make the plate thereof slightly negative when it is not conducting. `This can be compensated for by means of a Variable resistance as at 11 between the lixed resistances 46 and 41 of the bridge 45. Thesocalled contact potential effect of the diode 49 may `cause premature triggering of the diode shortly before the bridgeis in balance. Thus it `may be desirable carefully to adjust the variabl vswitching circuit, which is adapted for energizing the relay inone condition of said circuit and deenergizing same in another condition. The sequence switching circuit is consecutively changed from said first condition to said second condition by consecutive cycle change-over signals from the oscillator 48. Thus when the relay 31 is energized 7bit `remains. in `this state following a given cycle it change-over signal, until the-next cycle changeover signal at'whichftimethe relay is deenergizedi Thus the control valve 33 (Fig; 1i) isl heldl inone position by the spring 34 when the relay 3l is-deenergized and when the latter is energized the spring 34 is overcome and the solenoid 35 is adapted for urging same tothe opposite limit ofv its motion. Said trigger circuit, which governs said sequence switching circuit, is reset, that is, it is` prepared to emit the next succeeding signal by means of a suitable reset circuit which isresponsive, for a reason to appear hereinafter, bothA to the ,cycle change-over signal and the-stop reactivation signal.

It was'mentioned hereinbefore that the cycle change-over' signal is of predetermined duration. It is necessary for this signal to persist only' for a relatively short period in order to initiate the operation of the trigger circuit and the'sequence switching circuit. The trigger circuit in addition to initiating a cycle changeover signal also can initiate a start reactivation signal as will appear below. Immediately after the initiation of such an impulse for starting the reactivation, a stop reactivation signal may occur and may thus arrest the reactivation and prevent the rejuvenation of a wet desiccant bed. This, of course, must be prevented.

Itv was mentioned above that the trigger circuit,during the period of the cycle change-over signal, in addition to its normal function provides ashield toprevent an oncoming stop-reactivation signal from becoming effective. In the form of the invention shown, this so-called shield is effective for the duration of a stop-reactivation signal providing the latter occurs during a cycle change-over signal. able for the cycle change-over signal to beof adequate duration somewhat longer than any anticipated period of delay in generating the stop-reactivation signal. I have found that in machines of this type a delay of vone or twoseconds is as long as will be normally encountered in generating such a stop-reactivation signal. Consequently it is desirable for the above-mentioned stop-reactivation shield to be effective `for a period somewhat longer than said one or twcseconds. Consequently, the duration of the cycle Vchange-over signal preferably should be from about 3 to 5 seconds. Thus by the time the cycle change-over signal has expired, any delays in the generation of the stop reactivation cycle willl have taken place and during the time that said shield is effective.

The above-described multi-vibrator circuit is especially well adapted for producing a bridge balance signal (cycle change-over signal) of the above duration, and of non-hunting characteristics.

The non-hunt or anti-hunt property of said signal can be explained by the following characteristic of the multi-vibrator circuit acting in combination with (a) the dehumidifier, (b) the bridge 45, and (c) the diode49: when the bridge 45 has come into balance, immediately the valves 2217 and 23D are shifted and a blast of hot air strikes the resistor R-out, causing its resistance todecrease and thus brings the bridge back to its original unbalanced state. As the bridge passes out of the so-called null point or balanced condition, the oscillation of the multivibrator circuit does not instantly stop, that is, the cycle change-over signal persists for said period of, for example, 3 to 5 seconds. The reason for this is that although the plateY` of 4the Thus it is desir-y 12 diode' 49 ymay benegative with-i respect to the cathode, the negative peaks4 of the feedback voltage, as indicated in Fig. 8a, and aided by the so-called initial velocity of theelectrons leaving the cathode, are able to pass from the cathode to the anode to maintain oscillation1 for a predeterminable period during bridge unbalance and immediately after said valves are shifted. When said blast of hot air strikes R-out, thefpoint d of 'thebridge 45 isloweredin potential with respect to pointe. The lowering `of this potential is gradual andA is indicated: by the slope of the line-191 (Fig. 8a)` indicating the change in potentialof said pointd. Superimposed upon the representation of this changing potential is the oscillating feedback potential of the multi-vibrator. This oscillating potential lfor a short. while persists and extends below the curve ofthe gradually diminishing potential of the point d (Which also is the potential of the plate Vof diode 49).. The peaks thus are capable of extendingbelow this-curve for a time which is a function ofl (1) the slope of the line 19, and (2) the amplitude of the feedback potential. The latter amplitude is fixed and is a function of the resistance 6I. The slopefof `the line 19 in f turn depends upon the resistance change rate Lof R-out.

Ifsaid rate is great, the'slope ofthe line 19 (Fig. 8a). will be large and consequently `the time between on and .oif of the diode 49 will be quite shortA andl conversely. As above mentioned, it is desirable, however,V to select a resistance which, when the air valves are switched, will undergo a change Vadequate to produce such a slope that the` time between on and off will be between about 3 to 5 seconds.

-After, for example, said 5 seconds, depending Aupon the amplitude of Athe feedback potential', during bridge unbalance, and upon the resist- `ance 6l, the negative peaks (Fig. 8a.) can no -longerppass the line 11.9, that is, the electron flow resulting from the feedback potentialis runable :to passV from the, cathode tothe anode. At this point oscillation will stop abruptly and the plate `is so much. more .negative thanI the `cathode that once the oscillation has stopped, any feeble feedback surges appearing. at the cathode will be effectively blocked. Thus the circuit is provided with the so-called anti-hunt characteristic.

In the multi-vibrator circuit, the frequency and amplitude. of the oscillation are governed by suitable circuit constantsy andthe frequency and Wave form. are 4not of particular importance. Neither is; the .signal amplitude so, long as itis sufficiently high to; trigger a circuit `tolbe described hereinafter'. The Icycle' `change-over signal ygenerated by the multi-vibratoris of a voltage which is many times greater than, that required, in order to avoid the disadvantageous effects such as those due to the aging of the tubes and the variation of tubecharacteristics which may occur when a tube isreplaced.y

Sequence switching circuit or `counter circuit As above mentioned, the relay 3l', which is normally open, isconnected intoV a sequence switching or counter circuit'l-Sb in such a manner that it is alternately energized and deenergized by 4succeeding signals from said'multi-Vibratoren- -cuit through thel'intermediary'of a suitable trig- "geri'circuit 18a. -Such sequence switching circuit willbe rst described and thereafteritsactuating y'trigger circuit. i i f v i! In the form shown,- ithe sequence switching circuit comprises suitablethyratrons 88 and'8l which are connected in the manner of a so-called hip-flop circuit. The thyratrons 80 and 8| are connected to a plate supply voltage preferably of plus 200 volts as at 82 by means of leads 83 and 84, respectively, which in turn are connected to a master plate supply lead 82a. Interposed in the leads 83, 84 are the plate resistors 85 and 86. The cathodes of the thyratrons 88 and 8| are connected to ground by means of a lead 81, there being a suitable cathode bias resistor 88 interposed therein.

Suitable means not shown are employed for delaying the application or impression of the plate voltage of battery 82 by, for example, 30 seconds after the starting of the control apparatus.

A so-called commutating condenser as at 89 is connected across the plates of the tWo tubes 88 and 8| by means of a lead 98 which interconnects the plate supply leads 83, 84 at points intermediate the respective plates of said thyratrons and their respective plate resistors 85, 86.

The above-described relay 31 is connected in the lead 83. Thus whenever the thyratron 88 is conducting, a current will flow in the relay coil of relay 31 to energize same and conversely when the thyratron 88 is non-conducting, said relay will be deenergized.

The condenser 89 is referred to as a commu.

tating condenser or capacitor because it acts to shift the actuation or conduction of the thyratrons'88 and 8| alternately by changing the potential of their respective plates in a Well known manner in response to an initiating impulse to be described more fully hereinafter.

It is necessary in the operation of such a counter or flip-flop circuit for one of these thyratrons to be initially non-conducting and the other one initially conducting. In order to accomplish this, the grid, for example, of thyratron 88, has applied thereto a direct current potential of, for example, minus 18 volts which will suppress the operation thereof until the occurrence of an initiating impulse from the above-mentioned trigger circuit. Such a direct current potential is provided as by a battery 9| which is connected to the grid of thyratron 88 by means of a lead 92, there being a suitable grid bias resistance 93 connected therein. A grid bias resistance 94 is connected to the grid oi tube 8| by a grounded lead 95.

'Ihe grids of the thyratrons 88 and 8|, by means of leads 98 and 91, respectively, are connected to a common lead 98 through which the sequence switching initiating impulse is received from the trigger circuit above mentioned. Interposed in the leads 8B and 91 are capacitors 99 and |88, respectively.

When an impulse with a steep wave front, and of very short duration, is generated by said trigger circuit and applied to the grids of the thyratrons 88, 8| through said condensers 99 and |88, the initially non-conducting thyratron 88 will instantly conduct, thus: (a) energizing the relay coil 31, (b) closing the relay contacts 38, `(c) energizing solenoid 35 and moving valve 33 against spring 34 to one limit of its motion. Thyratron 8| (initially conducting) is simultaneously extinguished through the commutating capacitator 89. The next trigger impulse, whenever it appears, will switch the operation of the tubes 88 and 8| and thus will re the tube 8| causing it to extinguish the thyratron 88 via condenser 89 and consequently (a) to deenergize the relay 31, (b) open the contacts 38, and (c) permit spring 341to return valve 33to-its original position. Thus energization and deene'rgiz'ation of said relay will cause a switching of the dehumidier valves 22h and 23h.

From the above, it is seen that Whenever the multi-vibrator or bridge balance signalling means generates a signal, no matter of what duration, only a single but separate initiating impulse need be directed to the sequence switching or counter circuit. Such latter impulse must be of very short duration, lasting less than the de-ionization time of the thyratrons.

Trigger circuit The trigger circuit employs a thyratron trigger tube as at |8I. This tube is adapted for generating the above-mentioned steep wave front impulse which is capable of actuating the sequence switching circuit.

The trigger tube |8| normally is non-conducting by virtue of -a bleeder current which exists because of the connection of a direct current source |82 to the cathode of said trigger tube via a lead |82a and lead 98. The direct current source |82 provides, for example, plus 200 volts and its current flows through a resistance |83 in said lead |82a, and also through resistances |84, and |86 and thence to ground. The resistances |84 and |85 are interposed in a lead |81 which is connected to the cathode of the trigger tube |8| at point |81b and also connected with an on-off switching circuit |88 for a purpose to be described more fully hereinafter. Said resistance |88 is in a lead |89 which, by means of a lead ||8 is connected to said lead |81.

The lead |81 is also referred to as interlock A and its function will be more fully explained below.

The potential of the energy source |82 (plus 200 volts) is necessary to create a bias upon the grid of the trigger tube |8| and causes same t0 be normally non-conducting.

The plate of the trigger tube |8| is connected in a conventional manner by means of a lead to said plate supply lead 82a and has interposed therein a plate resistor ||.2.

The output lead 13 from the multi-vibrator 48 is electrically connected to the grid of the trigger tube |8|, there being a suitable condenser ||3 therein, together with a resistance ||4. The condenser I3, of course, prevents the passage of direct current to the trigger tube |8| and the resistance ||4 governs the amplitude of the signal to the grid of said trigger tube.

The grid resistor l5 for the trigger tube |8| is connected by a lead IIB to a point |810. of the lead |81 intermediate the resistances |84 and y A point 81h is maintained at a predetermined potential above ground due to said bleeder current. When a bridge balance signal is put out by the multi-vibrator 48, the trigger tube |8| is instantly red and the instantaneous flow of current from this tube through said resistances |84, |85 and |86 causes the potential of the point |811) suddenly to jump upwardly and thereby to produce the steep wave front impulse above mentioned.

This impulse is transmitted to the sequence switching thyratrons 88 and 8| through the condensers 99 and |88, respectively, and the sudden voltage jump causes one of said tubes 88, 8| to fire if it is non-conducting, and has no effect at all upon the other one. However, the ring of the non-conducting tube, for example, 88, will, through the intermediary of said commutating `condenser. 89, cause the conducting tube, for `ex .multi-vibrator signal stops.

:a-sian ample, 3.8i., '..to be extinguished. The jcondensers 98and 89 instantly Vstart togdischarge after-said voltage jump producing, a pulse form vas shown,

for example,rv at H7 inFig. 5.

Interlocking reset circuit This circuit is termed a reset circuit because once the trigger tube it! has .red, such circuit providesmeans for returning the tube to its initial non-conducting state whereby it is resetand prepared for re-ring upon the occurrence .of the next successive bridge balance signal from the multi-vibratorlt. Itfistermed an interlocking'reset circuit -because it is interlocked .in a

manner to appear more fully hereinafter with the reactivation side of the. apparatusA in order to :insure that a stop reactivation signal willbe ineiective should it occur duringra cycle change- .over signal or persistafter the expiration Yof the 4latter signal.

Once `the'trigger tube |8| has been red, it will remain conducting until it is extinguished. This extinguishment demands a negative impulse, from a suitable source such as reset tube H8, `to be applied to the anode or plate of the trigger tube Mil. The plate of the reset tube H8 by means of a lead H9, having asuitable plate resistor |28 therein, is also connected to said plate supply lead 82a. On the plate side of said plate resistors H2, l2|lalead I2! interconnects the plate leads ill and H9 of'tubes IBI and H8, respectively. A commutating condenser |22 is interposed in the lead 2l. Thus the above-mentioned negative impulse for arresting the opera- '1'tion ofrtrigger tube im is'communicated thereto through .thecommutating condenser' |22 in a manner somewhat similar to that explained in connection with the above-described commutatving condenser.

The reset tube H8 normally is without bias and in a conducting condition. However, when the trigger tube lili is fired by a signal from the multi-vibrator the reset tube H8 is extinguished. When the latter tube is extinguished, suitable means must be provided for preventing it from again conducting, not only until the bridge-balance signal from the multi-vibrator 48 vhasceased but, for reasons to be elaborated upon below, also until the bridge balance signal from the reactivation side-of the apparatus has ceased `refiring after it has been extinguished by the v '.triggerttube |85, the grid of the reset tube must gain control instantly after it is extinguished and before thegas therein can again ionize. accomplished by providing a negative bias voltage This is to the grid of said reset tube in the following imanner: the firstsignal pulse or bridge balance signal of the multi-vibrator 48 which fires the trigger tube iti is also applied to one of the grids of a dual triode amplifier tube |23. 'The output fof the latter tube is rectified by a diode |24 and la pulsating negative voltage appears at the plate of the latter. This pulsating voltage is smoothed and applied to the grid of the reset tube H8 through a resistance capacitance lter |25, |26. Thus the reset tube H has a negative bias'applied thereto and will not conduct until the bridge Abalance output signal ceases, that is, until the This .period is, forl provided on vthe reactivation side.

example,"from V3 Vvto .5` seconds. When the multivibrator signal disappears, the bias voltage will leak off through a suitable resistance |21 connected to the. plate of tube |24 and the bias voltage will .disappear whereupon the reset tube will .again instantly conduct and extinguish the trigger tube |0|.

.'I'hus whenever a bridge `balance signal is Atransmiseci from the multi-vibrator 4a, it not only fires the trigger tube |9| but sets in motionmeans for extinguishing said trigger tube. When the bridge balance signal from the multi- V.vibrator Y48 ceases, the trigger tube IDI is reset yand is prepared,'when itY receives the next succeedingbridge balance signal, to generate an `other impulse vfor the-sequence switching thyra- |23d, of course, is interposed Ybetween the plates of thetriode |23 and rectifier |24. The cathode of tube |24 is connected directly to ground.

The dual .triode |23, of course, is connected as a mixeramplifier with acommon plate resistor,'element |28, and with two separate inputs, each isolated from ythe other. Thus this dual triode can receive two separate input signalsi Reactivation side bridge bala'ncesrignaling means On .the `reactivation side of the `apparatus -a "reactivation exhaust temperature measuring bridge is employed whichV in general is similar to .the adsorption temperature diferential measuring bridge 45. Such a bridge is shown as at .133 and differs from the-bridge v45 in that only .onexthermistor |34 (RW) is used inthe bridge `as'one vof :the 'balancing arms. The remaining threearms |35, |36 and |3'lare fixed resistances.

.A reactivation bridge null detector oscillator,

'also vreferred to as a vbridge balance signalling means .is provided as at |38 which is identical to .the multi-Vibrator'48 .above described, except that the lmanually operable push button as at 13 'on the adsorption side of the apparatus is not The reason .for this'is that the Ybutton 13, in a manner to appear later, `isfada-ptedfor initiating not only aicycle change-over signal but also for starting reactivation. Consequently'it is unnecessary to have `suclrabutton or lswitch on this -reactivation Vside of the control.

Elements of the reactivation multi-vibrator |38 which correspond toelements of the adsorp- -tion 'multi-Vibrator 48 are designated by corresponding :numbers having added thereto the letter ".R.

When thereactivati'on exhaust temperature lhas reachedthe desired point, for example, TX V(Fig.'2), the bridge |33 Willfbe in balance and the multi-vibrator |38 willbe actuated 'to generateifabridge balance signalin amanner similar lto that described kabove infconnection ywith `the adsorption side bridge 45 andthe adsorption multi-vibrator 48.

The reactivation "bridge balance signalling means :governs the above-described relay -39 .(which lcontrols fthe reactivation 4hot air) through the intermediary of an ampliner circuit |39 and said on-oil switching circuit |08 above mentioned. The bridge balance signal from multi-vibrator |38 is amplilied by an amplifier tube |40 of said ampliiier circuit |39. Said multi-vibrator signal is directed to the ampliiier tube |40 by means of a lead |4| having therein a suitable capacitor |42 and resistance |43 which are analogous to the above-described capacitor and resistance ||3 and ||4, respectively. The lead |4| is connected to the grid of the tube |40 `and said grid in turn is connected to ground through a suitable grid resistance |44. The plate of the amplier tube |49 is connected by means of a lead |45 to a suitable plate supply 52 R analogous to the above-mentioned plate supply 52. A common plate supply can be employed if desired. A plate resistor |46 is interposed in said lead |45. The cathode of the tube |40 is connected by means of a lead |47 to a 4point |99a of said lead |09 and thence to ground through the above-described lead |09 and resistance |06.

The above-mentioned on-oir switching circuit |08 in general is constituted by a pair of thyratron tubes |43 and |49 which are interconnected in a manner somewhat similar' to the sequence switching thyratron.; 80 and 8| above described. The connections are similar in that the common plate supply 82a., for example, of plus 20() volts, is provided for said tubes |48, |49, the interconnection being accomplished through leads and |52 which are connected to a plate supply lead |50a. Suitable plate resistors |53 and |53a are interposed in said leads |5| and |52, respectively, and the coil of the above-described reaci i tivation fan relay 39 preferably is interposed in the lead 15| and hence is energized when the tube |48 is conducting.

The relay 39 is normally closed, that is, when the relay coil thereof is deenergized, the relay contacts as at (Fig. 1) are closed and the reactivation fan 29 is in operation. However, when the relay coil 39 is energized, the contacts or switch 40 will be opened and the reactivation fan 29 will be thus arrested.

The cathodes of the thyratrons |49, |49 are respectively grounded by the above-mentioned lead |99 and a lead |54, the latter lead being connected at a ypoint |54ct with the above-described lead ||0, and thence connected to the grounded lead |09 at point |090..

The plates of tubes |48 `and |49 are electrically associated by means of a lead |55 also having therein a commutating condenser |56 which serves a purpose analogous to the above-described comrnutating condenser 89 which is interposed between the plates of the sequence switching thyratrons 80, 8|. Thus if one of the on-o switching circuit thyratrons |48, |49 is normally in a non-conducting condition, it can be irefl by the other thyratron in a manner analogous to the sequence switching thyratrons. In order to insure that one of the thyratrons |48, |49 is initially non-conducting, a potential of, for example, minus l0 volts, is impressed upon the grid of, for example, tube` |48. Such a source or potential is indicated as at 9|a and is connected to the grid of the tube G48 by means of a lead 458, there being interposed in said lead a grid resistor 59.

Inasrnuch as the thyratron |48 is selected as the one to be initially non-conducting, and the one in the plate circuit of which is interposed the reactivation relay 39, this tube (|48) is placed under the inuence of the amplifier tube |40. That 18 is, the grid of the tube |40 by means of a lead |60 is connected to the plate of the amplifier |40, there being a suitable capacitor |6| in the lead If we now assume that the wet air exhaust temperature has reached the desired temperature (TX), the so-called cut-out point, a signal will be generated by the multi-vibrator |38 calling for a stopping of reactivation. A part of the Voltage of `this signal is amplied by the amplier tube |40 and employed to fire the initially non-conducting thyratron |48. Notice that this signal is sent only to the one thyratron |48 and not to both thyratrons |48, |49 as is the case with the actuating impulse directed to the sequence switching circuit above described. The reason for this is that the next or ensuing stop reactivation signal must not be permitted to extinguish the thyratron |49 as would be the case if the amplier |40 were connected to both of the tubes |48, |49 in a manner analogous to the association of the trigger tube |0| and the sequence switching thyratrons. The control of the thyratron |49 must remain, for a reason to appear hereinafter, partially in the adsorption side of the apparatus and more: particular in the trigger tube |0|. The thyratron |49 is initially conducting when the thyratron |48 is fired through the intermediary of the :amplifier |40 in response to a stop reactivation signal which iiring will extinguish tube |49. Moreover, the firing of the thyratron |48 will, of course, energize the relay 39 and hence will open its 'normally closed contacts 40 (Fig. 1) and arrest the reactivation fan 29.

Normally the stop reactivation signal will be generated somewhat in advance of the cycle change-over signal. Consequently, when the latter is produced, it should initiate the next reactivation cycle in addition to initiating the cycle change-over. The cycle change-over signal,4 namely, the bridge balance signal of the adsorption multi-vibrator 48, is effective to initiate reactivation through the intermediary of the above-described trigger tube |0| which, by means of a lead |62 having therein a capacitor |63, is in control of the grid of the thyratron |49,` the grid of the latter tube being grounded in a conventional way through a grid resistor |54.

Thus normally or under most conditions, the sequence of operation of the reactivation and adsorption sides of the apparatus will not tend to be upset. However, there are certain examples of the operation wherein the time of the reactivation and the time of the adsorption cycle may be approximately equal and upon completion of the adsorption cycle the valves 22h and 23h are switched to their next position and a start reactivation signal is directed to the tube |49 from trigger tube |0| via lead |62 (interlock C). If, during the cycle change-over signal, there is a slight delay in the generation of the stop reactivation signal, the latter may be directed to the on-off switching circuit |08 via the amplifier circuit |39, after the occurrence of the start reactivation signal from the trigger tube |0|, providing, of course, the adsorption and reactivation cycles are approximately or" equal duration. If this occurs, one of the decissant beds will ordi.- narily have its reactivation process arrested at the very outset and will remain wet, thereby preventing a proper adsorption cycle on the next switch of the Valves 22h, 23h. Such a delay in the generation of the stop reactivation signal may be caused by a delay in the response of the thermistor RW.

Suitable means are provided for preventing such a delayed stop reactivation signal from arresting reactivation provided, of course, that it occurred or was at least partially co-extensive with the cycle change-over signal generated by the adsorption side of the apparatus.

Such novel means comprise the following:

(a) .A primary bias increase applied to amplier tube |40. When the thyratron |49 is conducting, the voltage drop across resistance |06 is just suicient to provide a normal bias for the amplifier tube |40. However, the on-Off circuit |08 is so designed that when the thyratron |48 is fired, an extra amount of current flows therethrough and returns to ground through resistance |06. This extra current through resistance |06 provides theprimary bias increase for the amplier tube |40 and increases its bias to the so- .called cut-oif point whereby the tube will no longer amplify. Thus the eiect of a persistent stop reactivation signal is nullied with respect to the on-01T switching circuit |08 and no more of this particular stop reactivation signal will reach the thyratron |48. Thus the possibility of upsetting the sequence of the circuit by an unduly persistent stop reactivation signal is prevented. vThis so-called primary bias increase for the thyratron |40 will, of course, persist only so long as the thyratron |48 conducts. When the latter `isextinguished as by the firing of the thyratron Y| 40 in response to a cycle change-over signal from the trigger tube |I, a so-called secondary bias increase will be applied to the amplifier |40 in a manner to appear below. y (b) A secondary bias increase for the amplier tube |40. When the trigger tube |0| is red it also res the thyratron |49 of the on-olf switching circuit. This firing of the thyratron |49 extinguishes the thyratron |48, thus terminating -the above-described primary bias increase for the amplifier tub-e |40. Thereupon, a so-called secondary bias increase for the same amplier tube arises, as a result of the operation of the trigger tube 0|, through the intermediary of the above-described so-called interlock A or lead |01, whereby an additional potential is applied to the point |00a on the reactivation side which normally will so influence the bias of said amplier tube that its amplication will be prevented entirely and thus the thyratron |48 will vbe main- .tained in a non-conducting condition. Also the reactivation fan relay 39 will be deenergized, whereby the reactivation fan will be maintained y in operation.

g The above-described bias increases for the amplier tube |40 are effective only while thyratron |48 is conducting and thereafter while the trigger tube |0| is conducting. Thus in the absence of any further interconnection between the adsorption and reactivation sides of the control, these shields in the form of the shielding bias voltages would be elective only up to the expiration of the cycle change-over signal. However, there is a possibility that under some circumstances a stop reactivation signal may occur during a "cycle 'change-over signal and persist after the expiration thereof in which case the re-activation would be arrested at an undesired time and upset the- `sequence of operations of the device.

Thus some means must be provided for con-y tinuing the effect of the shielding bias such as the secondary bias increase for the amplifier tube 40. The latter bias increase, of course, is the result of the operation of the trigger tube |0|. Consequently, if some means can be provided for.'

20 extending the operation of the trigger tube |0| as long as there is a stop reactivation signal then, of course, it would be impossible for the latter signal to re the thyratron |48 and hence to stop the reactivation.

The novel interconnection for extending the operation of the said trigger tube is constituted by a so-called Interlock B or lead |65.

The lead |05 interconnects a point |4|a of lead |4| with a grid of dual triode |23, that is, the output signal of the reactivation multi-vibrator |38 is directed to the mechanism which is designed for controlling the reset tube H8. Point |4|a of lead |4| is preferably intermediate condenser |42 and resistance |43. It was explained above that the interlocking reset circuit is designed for extinguishing the trigger tube |0| after the expiration of the cycle change-over signal, and thus to prepare the trigger tube for the next output signal from the adsorption multivibrator 43. The Interlock B above mentioned is adapted for delaying the extinguishing of the trigger Vtube |0| by extending the length of time that the grid of the reset tube I3 controls same and maintains it in a non-conducting condition. If, for example, We assume that the cycle changeover and the top reactivation signals commence precisely at the same instant and that the former endures for ten time units and the latter for twelve time units it will be evident that Without the Interlock B (lead the above-described secondary bias voltage will cease after ten time units and the stop reactivation signal will be effective to re the thyratron |48 and thus to stop the reactivation which was begun as a result of the ring of tubes |0| and |49. However, by virtue of the feeding of the stop reactivation signal into the interlocking reset circuit, the extinguishing of the trigger tube |0| is delayed until the expiration of said twelfth unit of time and consequently the secondary bias increase voltage for the amplifier tube |40 is caused to persist until the expiration of said twelfth time unit. Thus the delayed and undesired stop reactivation signal is incapable of triggering the thyratron |48 and of stopping reactivation.

Of course, the stop reactivation signal voltage cannot have any effect upon the interlocking reset circuit or upon the reset tube H0 unless the grid of the latter tube is in control thereof. In other Words, in order for the stop reactivation signal to be effective to delay the extinguishment. of trigger tube |0| and hence to extend the existence of th-e above-described secondary bias voltage as long as a stop reactivation signal persists, it is necessary for said stop reactivation signal to be at least partially co-extensive with a corresponding cycle change-over signal. If the stop reactivation signal were directed to the interlocking reset circuit when the reset tube ||8 is in its normally conducting condition, it will have no effect thereon.

In operation, let us assume for a rst example thereof that the novel control is operating under relatively low moisture conditions, that is, under conditions wherein the adsorption cycle will be substantially longer than the reactivation cycle. Moreover, let us assume that the temperature R-in is Zero degrees Fahrenheit. It will be observed from Fig. 6 that when R-in is Zero degrees Fahrenheit a desired temperature differential for cyclechange-over is 16 F. Throughout the adsorptioncycle the temperature R-in will remain substantially constant. When Tz-Ti is equal to 16 the adsorption bridge -45'will be in balance and the rectiiier 49 will be triggered, whereby the multi-vibrator 48 is actuated and an output or bridge balance signal is directed to the trigger tube Il. The normally non-conducting trigger tube IUI will be red, thereby extinguishing the normally conducting reset tube I I8. The bridge balance signal from the multi-vibrator 48 also is fed to the interlocking reset circuit, and by means of the dual triode |23, the rectifier tube |24 and related elements causes the grid of the reset tube I I8 immediately to gain control thereof, which control persists at least for the duration of the bridge balance signal.

The ring of the trigger tube IIII has the following eiects: (a) Switches the valves 22h, 23D by firing the sequence switching thyratron 80, the latter extinguishing the sequence thyratron 8| via the commutating condenser B9. The ring of the thyratron 80, of course, energizes the relay 3'I and by means of the solenoid 35 changes the position of valve 33 of power cylinder 3.2 and hence shifts the above-mentioned cycle changeover valves 22h, 23h.

(b) Starts reactivation. This is accomplished by means of a simultaneous eiiect of the iiring of trigger tube IIiI upon the on-oil switching circuit |08. The sudden change in potentialof the point I'I'b not only changes the bias of the grid of thyratron 8G to the extent that it conducts whereas theretofore it was non-conducting, but it also triggers the on-off thyratron |49 which is normally non-conducting, extinguishes thyratron |48, thereby deenergizing the relay coil 39, closing the switch 40, and starting reactivation.

Sometime prior to the balancing of the adsorption bridge 45, the reactivation bridge |33 comes into balance by virtue of the wet air exhaust temperature reaching Trc. This has the effect of actuating the multi-vibrator |38, the outputsignal of which is directed to the amplifier |39 and thence to the on-off switching circuit, that` is, to the tliyratron |48, which is normally and initially non-conducting, thereby firing tube |48 and energizing relay 39, which in turn opens switch 40 vand stops reactivation.

' In the second example of the operation of the device, assume that the novel control is operating under substantially maximum moisture conditions under which circumstances `the adsorption and reactivation cycles will be about equal in duration. Furthermore, assume that the adsorption side of the apparatus has operated in the manner above described and has generated a start reactivation signal which is directed from tube IUI to the reactivation side via the lead |62. If the reactivation cycle is still under Way at the time that the cycle change-over signal is generated, it is, of course, desirable for the reactivation to continue after the valves 22h, 23h have been changed. Thus upon the cycle changeover, namely, the switching of the valves 2217, 23h, Rw will suddenly be subject to the lowest temperature as indicated in Fig. 2 on the line T4.

However, it may be possible thereafter for the bridge to move into balance and to generate a delayed bridge balancing signal which, without the novel interconnection between the reactivation and adsorption side of the apparatus, would arrest the reactivation oi a wet desiccant bed. It was mentioned above that the cycle changeover signal will persist for from 3 to 5 seconds during which time the above-mentioned trigger tube IDI will, by virtue of its conduction, apply the above-described secondary bias increase or 22 shielding bias to the amplier tube |40. If the "stop reactivation signal is delayed in starting but commences during the cycle changeover signal and persists thereafter, `said secondary bias voltage will also persist until the expiration of the stop reactivation signal. This is accomplished by applying the stop reactivation impulse to the above-mentioned interlocking reset circuit by the Interlock B (lead |65). Thus the period of operation or conduction of the trigger tube IIlI is extended "until the expiration of the stop reactivation" signal and said shielding bias is co-extensively prolonged whereby the undesired reactivation signal is incapable of stopping reactivation. Thus reactivation is allowed to continue but in view of the cycle change-over upon a different desiccant bed.

While the invention has been described with respect to certain preferred examples which have given satisfactory results, it will be understood by those skilled in the art after understanding the invention that various changes and modifications may be made without departing from the spirit and scope of the invention, and it is intended therefore in the appended claims to cover all such changes and modifications.

In this specication and the following claims the terms vacuum tube and electron tube both refer broadly to high vacuum devices functioning by electron emission control, and the term thermionic valve or the like expression is intended as a generic expression to comprehend the said devices and those of similar character, whether using a hot cathode or a cold emitter. These terms also include the associated circuits necessary for the operation of the tubes.

What is claimed as new and is desired to be secured by Letters Patent is:

l. In apparatus of the class described, the combination comprising: an electronic multi-vibrator including a pair ol electronic tubes each having a control grid and an anode, a connection between the control grid of each tube to the anode of the other tube, one such connection including a` conjugate arm of a balancing bridge in shunt with a diode having its anode coupled to the control grid of one of said tubes, and its cathode directly connected to such bridge, said bridge including a pair of fixed ratio balancing arms and a pair of balancing arms containing temperature sensitive elements; an opposite conjugate arm of said bridge an said diode being adapted for use with a direct current source of electrical energy for energizing same; said bridge responding to a balanced condition of said temperature sensitive elements to energize said diode and thereby to energize said multi-vibrator; and a control device responsive to energization of said multi-vibrator for influencing `the temperature conditions of said temperature sensitive elements.

2. In a control device of the class described,

`a normally inactive multi-vibrator; means for activating the latter including a conjugate arm of a balancing bridge in shunt with a rectifier connected in feedback relation with said multi-vibrator, said bridge and rectifier being electrically coupled to said multi-vibrator, said bridge having as two balancing arms thereof temperature sensitive devices; means responsive to a balanced condition of said bridge thereby to energize said rectifier; and a control device responsive to energization of said multi-vibrator for influencing the temperature condition of said temperature sensitive devices.

3. In apparatus of the class described, a pair 23 of desiccant beds; mechanism for selectively directing intake air to either one of said beds for an adsorption cycle; mechanism for selectively directing heated air to either one of said `beds for a reactivation cycle; temperature responsive resistance elements for sensing the temperature of the air at the inlet and outlet of each of said beds, said elements being adapted for measuring the temperature differential between the inlet and outlet air temperatures of the bed which is undergoing an adsorption cycle, and for measuring the exhaust temperature of the bed undergoing a` reactivation cycle, said elements also being subject to a preselected change in resistance in respense to predetermined temperature changes whereby for preselected temperature differentials therebetween the resistances thereof are equal; means responsive to said elements reaching equal values of resistance when a bed is undergoing adsorption for terminating the ilow of adsorption air thereto and initiating a iiow of reactivation air thereto; and means for terminating a flow of reactivation air to a bed undergoing reactivation in response to an outlet temperature resistance element reaching a preselected resistance value.

4. In apparatus of the class described, `a desiccant bed; adsorption cycle mechanism for directing a gas through said bed for adsorbing moisture therefrom during an adsorption cycle; reactivation cycle mechanism for directing a heated gas through said bed for reactivating same during a reactivation cycle; an inlet thermal resistance element for sensing the temperature of the influent gas to said bed, the resistance of said element being variable between predetermined limits in response to temperature change also between predetermined limits; an outlet thermal resistance element for sensing the temperature of the effluent gas from said bed, the resistance ofv said outlet element alsofbeing variable between the same predetermined limits in response to ay change of temperature between preselected limits whereby the resistances of said elements are of equal value over a predetermined range of temperature differentials therebetween; ybalance sensing means for sensing a balance between the resistances of said elements; means operatively connected to said balance sensing means for rendering inoperative said adsorption cycle vmechanism and for initiating said reactivation cycle mechanism; a temperature responsive element for tive said reactivation cycle mechanism and initiating the operation of said adsorption cycle mechanism.

5. In a control mechanism the combination including, a heat responsive resistance element `adapted for changing resistance within predetermined limits in response to temperature change between preselected limits; another heat responsive resistance element also adapted for changing resistance within the same limits as the rst-mentioned element in response to temperature change between limits which are different from those of said Erst-mentioned element whereby the resistances of said elements can be equal but a variable temperature differential exists therebetween in response to joint resistance changes while the resistances remain equal; and means responsive to said resistances becoming `equal for initiating an electric impulse.

6. Ina control of the class described the combination including a pair of resistances response respectively to the heat of iluid attwo differentY locations, said resistances beingequal over a preselected range of temperature differentials there'- between; means for responding to a balance of said resistances; and mechanism controlled by said last-named means for governing the movement of said fluid'. i

7. In a control device for an apparatus wherein influent and eilluent fluids flow relative thereto, the combination including, a pair of resistances responsive respectively to the temperaturefof the iniiuent and eiiluent fluids, said resistances being equal over a preselected range of temperature differentials therebetween, the temperature differential being a function of the temperature of the influent uid; means for creating an impulse vin response to said resistances coming intobalance;` and means for governing the ilow of the uidin response to an impulse from said last-named means.

8. In a control device for an apparatus wherein influent and effluent gases now therethrough, mechanism for forcing gases through the apparatus; a pairof resistances responsive respectively tothe temperature of the influent and eluent gases, said resistances being equal over a preselected range of temperature differentials between the resistances whereby the temperature of the inuent gases can be substantially constant for the duration of one cycle of operation of the control device and the resistances will Ibecome equal at a predetermined temperature .differential for that cycle, and the iniluent gas temperature can again be substantially constant but different from that first mentioned for another cycle of operation, the resistances becoming equal at another and different predetermined temperature diirerential; means for creating an impulse in response to said resistances coming into balance; and means for controlling the flow of gases through the apparatus in response to an impulse from said last-named means.

9. In apparatus for governing a control device the combination including: a bridge circuit having therein a pair of resistances having negative temperature coeflicients and being subject respectively to iiuid at different temperatures, said resistances being equal over a preselected range of temperature differentials therebetween; a bridge null detector circuit, which is normally quiescent but is adapted for transmitting an impulse in response to said resistances coming into balance; an oscillator circuit connected into and actuatable by said bridge null detector circuit in response to an impulse therein; and means responsive to an output impulse of said oscillator circuit for actuating the control device.

l0. In apparatus of the class described for governing a control element: a pair of resistances responsive respectively to a iirst and second range of changing temperatures, said resistances varying in preselected manners over said ranges whereby the resistances thereof are equal over a preselected range of temperature differentials therebetween; a normally inactive thermionic valve electrically connected to said resistances andsrendered operative in response to said resistances coming into balance, said valve being rendered inoperative a preselected time aftersaid resistances become balanced; an oscillator circuit controlled by said thermionic valve; and means responsive to successive output impulses of said oscillator circuit for alternately energizing and deenergizing the control element. Y

25 y 11. In apparatus for use in combination with a pair ci desiccant beds having a valve mechanism for directing intake air from an intake pump selectively to either one of the desiccant beds for an adsorption cycle and for simultaneously directing heated air from a hot air pump to the other bed for a reactivation cycle, the combination comprising: a valve mechanism control device for switching the position of said valve mechanism whereby the cycles to which said beds are subjected are switched; a control element for the hot air pump; a `normally inactive electronic multi-vibrator including a pair of electronic tubes each having a control grid andan anode, a connection between the control grid of each tube to the anode of the other tube, one such connection including a conjugate arm of a balancing bridge in shunt with a diode having its anode coupled to the control grid of one of said tubes, said bridge including a` pair of fixed ratio balancing arms and a pair of balancing arms containing temperature sensitive elementsJ the latter pair of elements being n respectively associated with the desiccant beds another through a commutating condenser, said valve mechanism control device being electrically associated with one of said sequence switching circuit thyratron tubesfcr switching the valve mechanism in response to energization of such thyratron; a trigger circuit including a normally non-conducting trigger thyratron tube electrically associated with said multi-vibrator and i said sequence switching circuit for actuating the latter in response to a signal from said multivibrator; a reset circuit for said trigger tube including a normally conducting reset thyratron tube associated with said trigger tube through the intermediary of a commutating condenser whereby the reset tube is extinguishable in response to the ring of said trigger tube and vice versa, said reset circuit also including electronic means for controlling said reset tube to prevent the nring thereof for the duration of a signal emanating from said multi-vibrator, a second multivibrator analogous to that above set forth, one of the connections thereof between a control grid of one tube and the anode of the other tube thereof also including a conjugate arm of a balancing bridge in shunt with a diode, said bridge including three fixed ratio balancing arms and a balancing arm containing a temperature sensitive element, the latter element being positioned for sensing the outlet air temperature of the bed undergoing a reactivation cycle; an amplifier for receiving and amplifying the signal of said second multi-vibrator; an on-oii" switching circuit including a pair of thyratron tubes being interconnected through a commutating condenser and having associated therewith said control element for the hot air pump, one of said onoi switching circuit thyratron tubes being normally non-conducting and adapted for extinguishing the other on-oi switching circuit thyratron in response to a signal from said amplier, said hot air pump control element being' operatively associated with said last-mentioned normally non-conducting thyratron; an electrical interconnection between said trigger circuit and said cn-of switching circuit for actuating said hot air pump control element to start a reactivation cycle in response to energization of said trigger tube; a second electrical interconnection between said trigger circuit and said onoff switching circuit and said amplifier for increasing the bias of said amplier to the cut-off point during the energization or said trigger tube; and an electrical interconnection between said second multi-vibrator and said reset tube for maintaining the latter in a non-conducting condition in response to the reception thereby of a signal from said second multi-vibrator which is at least partially co-extensive with a signal from said first-mentioned l multi-vibrator.

l2. In a control device of the class describedy a normally inactive multi-vibrator including a rst control grid and anode and a second control grid and anode, a connection between the nrst control grid and the second anode and a connection between the second control grid and the first anode, one such connection including a conjugate arm of a balancing bridge in shunt with a rectifier electrically associated with said multi-vibrator for providing feedback oscillations in the multi-vibrator, said bridge including a pair of fixed ratio balancing arms and a pair of balancing arms containing temperature sensitive elements, an opposite conjugate arin of said bridge and said rectifier being energizable by a source of electrical energy, said bridge responding to a balanced condition of said temperature sensitive elements to energize said rectifier and thereby to energize said multi-vibrator, the latter being normally quiescent; a control device responsive to energization of said multi-vibrator for iniluencing the temperature conditionsof said temperature sensitive elements; said multi-vibrator generating a signal of predeterminable duration; a third temperature sensitive element; a control element responsive to said third temperature sensitive element reaching a preselected temperature for actuating said control element and influencing the temperature conditions of said third temperature sensitive element; an operative interconnection between said multivibrator and said control element for actuating the latter in response to a signal from said multi-vibrator; and an operative interconnection between said third temperature sensitive element and said control device for preventing actuation of said control element in response to said third temperature sensitive element reaching a preselected temperature during the generation of a signal by said multi-vibrator.

13. In apparatus for use with a pair of desiccant beds having a valve mechanism for directing intake gas from an intake pump selectively to either one of the beds for an adsorption cycle and for simultaneously directing heated gas from a second pump to the other bed for a reactivation cycle, the combination including: a valve mechanism control device i or switching said valve mechanism whereby the pumps with which said beds are in communication are also switched; a control element for the second gas pump; a normally inactive electronic multi-vibrator including a iirst control grid and anode and a second control grid and anode, a connection between the rst control grid and the second anode and a connection between the second control atei-,441

27 grid and the first anode, one such connection including a conjugate arm of a balancing bridge in shunt with a diode having its anode coupled to the control grid of one of said tubes, said bridge having as two balancing arms thereof temperature sensitive elements; said bridge being energizable by a source of electrical energy; said diode and multi-vibrator being normally quiescent and 'energized in response to a balancedg control circuit for actuating said second pump in response to a signal from said multi-vibrator; and a 4second operative interconnection between said second control circuit and said rst control circuit for rendering the former inoperative with respect to said control element in response to said third temperature sensitive element reaching a preselected temperature during the period of a signal from said multi-vibrator.

14.`In apparatus for use with a pair of desiccant beds having a valve mechanism for directing intake air from an intake pump to either one of the desiccant beds for an adsorption cycle in such bed and for simultaneously directing a reactivation gas from a reactivation pump to the other bed for a reactivation cycle, the combina- 'tion including: a valve mechanism control device foixswitching the valve mechanism and thereby switching the pumps with which said beds are in communication; a control element for the reactivation pump; a pair oftemperature sensitive resistances positioned respectively for sensing thetemperature of the intake and outlet air of the desiccant bedundergoing an adsorption cycle, said resistances being electrically equal over a preselected range of temperature ,diierentials therebetween; electronic means for generating` a cycle change-over signal of predeterminable duration in response to said resistances coming into balance; said valve mechanism control device being operatively associated with said cycle change-over generating means for switching said valve mechanism in response to a cycle changeover signal; a `reactivation exhaust temperature sensing element positioned for sensing the temperature of the exhaust from the desiccant bed undergoing a reactivation cycle; means for generating a stop reactivation signal in response to a preselected reactivation exhaust temperature as sensed by said last-named element; said reactivation pump control elem'ent being operatively connected to said stop reactivation signal generating means; a first operative interconnection between said cycle change-over signal generating means and said reactivation pump control element for actuating said reactivation pump; and a second operative interconnection between said stop reactivation signal generating means and said cycle change-over signal generating means for rendering inefective a stop reactivation signal which is at least partially coextensive with a cycle change-over signal.

WYAN LOU.

REFERENCES CITED The following references are of record inthe idle of this patent:

UNITED STATES PATENTS Number Name Date 2,257,478 Newton Sept. 30, 1941 2,275,452 Meacham Mar. 10, 1942 2,328,974 Guler Sept. 7, 1943 2,366,076 Wilbur Dec. 26, 1944 OTHER REFERENCES Radio News, August 1946, pages 15-17, 20 and 23 of Engineering Dept. 

